Presented is a lateral fin static induction transistor including a semi conductive substrate, source and drain regions extending from an optional buffer layer of same or varied thickness supported by the semi conductive substrate, a semi conductive channel electrically coupling the source region to the drain region of the transistor, a portion of the semi conductive channel being a fin and having a face covered by a gated structure, thereby defining a gated channel within the semi conductive channel, the semi conductive channel further including a drift region electrically coupling the gated channel to the drain region of the transistor.

A vertical SiC MOSFET having a source terminal, a drain terminal, and a gate region, as well as an epitaxial layer disposed between the source terminal and the drain terminal and having a doping of a first type, is furnished, a horizontally extending intermediate layer, which has regions having a doping of a second type different from the doping of a first type, being embedded into the epitaxial layer. The vertical SiC MOSFET is notable for the fact that at least the regions having doping of a second type are electrically conductively connected to the source terminal. The gate region can be disposed in a gate trench.

A method of manufacturing an insulated-gate semiconductor device, includes: digging a gate trench and a dummy trench; burying a dummy electrode in the dummy trench via a gate insulating film and burying a gate electrode in the gate trench via the gate insulating film; exposing an upper portion of the dummy electrode and selectively forming an insulating film for testing so as to cover the gate electrode; depositing a conductive film for testing on the dummy electrode and the insulating film for testing; and selectively testing an insulating property of the gate insulating film in the dummy trench by applying a voltage between the conductive film for testing and the charge transport, region.

A semiconductor film, a sheet like object, and a semiconductor device are provided that have inhibited semiconductor properties, particularly leakage current, and excellent withstand voltage and heat dissipation. A crystalline semiconductor film or a sheet like object includes a corundum structured oxide semiconductor as a major component, wherein the film has a film thickness of 1 m or more. Particularly, the semiconductor film or the object includes a semiconductor component of oxide of one or more selected from gallium, indium, and aluminum as a major component. A semiconductor device has a semiconductor structure including the semiconductor film or the object.

A high voltage device includes: a semiconductor layer, a well, a body region, a gate, a source, a drain, a drift oxide region, and a top region. The well is formed in the semicoducotor layer. The body region is formed in the well. The gate is formed on the well. The source and the drain are located below, outside, and at different sides of the gate, in the body region and the well respectively. The drift oxide region is formed on a drift region, wherein a bottom surface of the drift oxide region is higher than a first trench bottom surface of the first trench. The top region is formed in the well right below the drift oxide region, and is in contact with the drift oxide region.

A semiconductor film, a sheet like object, and a semiconductor device are provided that have inhibited semiconductor properties, particularly leakage current, and excellent withstand voltage and heat dissipation. A crystalline semiconductor film or a sheet like object includes a corundum structured oxide semiconductor as a major component, wherein the film has a film thickness of 1 ?m or more. Particularly, the semiconductor film or the object includes a semiconductor component of oxide of one or more selected from gallium, indium, and aluminum as a major component. A semiconductor device has a semiconductor structure including the semiconductor film or the object.

A method of forming a semiconductor device includes etching a semiconductor layer to form a plurality of mesa stripes in the semiconductor layer. The plurality of mesa stripes extend in a first direction and include mesa sidewalls that extend in the first direction and mesa surfaces at opposite ends of the mesa stripes. An additional mesa region is formed at an end of at least one of the mesa stripes. The additional mesa region is electrically insulated from the at least one of the mesa stripes. A semiconductor device structure includes a plurality of mesa stripes that extend in a first direction and include mesa sidewalls that extend in the first direction and mesa end surfaces at opposite ends of the mesa stripes. An additional mesa region that is electrically insulated from the at least one of the mesa stripes is at an end of at least one of the mesa stripes.

The field effect transistor (FET) of the present subject matter comprises a bottom gate electrode, a bottom gate dielectric provided on the bottom gate electrode, a channel layer provided on the bottom gate dielectric. A top portion comprising a source electrode, a drain electrode, a top gate electrode provided, and a top dielectric layer is provided on the channel layer. The channel layer forms Schottky barriers at points of contact with the source and the drain electrode. A back-gate voltage varies a height and a top-gate voltage varies a width of the Schottky barrier. The FET can be programmed to work in two operating modes-tunnelling (providing low power consumption) and thermionic mode (providing high performance). The FET can also be programmed to combine the tunnelling and thermionic mode in a single operating cycle, yielding high performance with low power consumption.

Presented is a lateral fin static induction transistor including a semi conductive substrate, source and drain regions extending from an optional buffer layer of same or varied thickness supported by the semi conductive substrate, a semi conductive channel electrically coupling the source region to the drain region of the transistor, a portion of the semi conductive channel being a fin and having a face covered by a gated structure, thereby defining a gated channel within the semi conductive channel, the semi conductive channel further including a drift region electrically coupling the gated channel to the drain region of the transistor.

Presented is a lateral fin static induction transistor including a semi conductive substrate, source and drain regions extending from an optional buffer layer of same or varied thickness supported by the semi conductive substrate, a semi conductive channel electrically coupling the source region to the drain region of the transistor, a portion of the semi conductive channel being a fin and having a face covered by a gated structure, thereby defining a gated channel within the semi conductive channel, the semi conductive channel further including a drift region electrically coupling the gated channel to the drain region of the transistor.